Hydroponic cultivation apparatus and method

ABSTRACT

An apparatus which includes a growing container in which plants are hydroponically grown on a support medium is disclosed. The growing container includes a plurality of openings in which seals are installed. The seals include holes through which the plants grow. When seeds are planted, a hollow tube is placed through the seal hole to maintain the seed in position. After the seed germinates, it grows through the tube. As continued growth expands the plant&#39;s stem to the size of the tube, the tube breaks apart and does not constrain future plant growth. Moreover, as the plant grows further, the seal hole expands to accommodate the plant stem. The seal surrounds and contacts the plant stem to reduce evaporation of nutrient solution from the growing container and to keep insects and contamination out of the growing container. A holding container is positioned above the growing container and coupled to the growing container through a manifold arrangement. The holding container may be quickly filled with a single, measured nutrient solution charge for the growing container. Then, a valve is opened, and the manifold arrangement slowly distributes the nutrient solution to the growing container where it is substantially absorbed by the support medium and wicked to the vicinity of the plant within the growing container.

CROSS-REFERENCE TO RELATED APPLICATIONS

This is a division of U.S. Pat. No. 08/087,506 filed Jul. 2, 1993 andnow U.S. Pat. No. 5,381,626 which is a continuation-in-part of U.S.application Ser. No. 07/625,078, filed 10 Dec. 1990 now U.S. Pat. No.5,224,291.

FIELD OF THE INVENTION

The present invention relates generally to horticultural devices andmethods. More specifically, the present invention relates to hydroponicdevices and methods which are particularly adapted for outdoor plantcultivation.

THE PRIOR ART

Hydroponics generally represents the growing of plants in nutrientsolutions rather than in natural soil. For many horticulturalapplications, hydroponics provides significant benefits. For example,greater control may be exerted over the parameters which affect plantgrowth. Consequently, plant densities, plant growth rates, and productyields may exceed those achievable by cultivating plants in naturalsoil. Moreover, soil or other environmental conditions in variouslocations simply prohibit successful cultivation of certain plants. Inthese situations, such certain plants may be successfully cultivatedusing hydroponic techniques.

On the other hand, hydroponic techniques conventionally presentsignificant drawbacks. The control of numerous parameters which affectplant performance usually requires a substantial investment infacilities and equipment. Often, hydroponic techniques are practicedindoors, in greenhouses and 6 the like, where plantperformance-affecting parameters may be more easily controlled thanoutdoors. The indoor facility needs, when coupled with elaborateequipment needs, often make such conventional hydroponic techniquesprohibitively expensive. In addition, indoor space limitations oftenrestrict the practice of conventional hydroponic techniques to a smallscale. Furthermore, elaborate equipment often requires a great amount ofhuman intervention and maintenance in order to achieve successfulhydroponic results. Often times, a failure of a single piece ofhydroponic equipment results in failure of an entire crop.

Still, in many potential applications some or all of the advantages ofhydroponic techniques can be achieved without indoor facilities.Consequently, by practicing hydroponics outdoors many of the cost,space, and other disadvantages are minimized. While outdoor hydroponicsystems are known, such conventional outdoor systems fail to adequatelyanswer many of the problems posed by outdoor hydroponics.

For example, in arid climates hydroponics potentially offers greatbenefits because the successful cultivation of certain desirable plantsin arid soil is exceedingly difficult. However, in arid climatesevaporation of nutrient solutions becomes a serious problem. Evaporationmay take place from a plant itself or directly from hydroponicequipment. Substantial evaporation from hydroponic equipment isespecially undesirable because such evaporation may undesirablyconcentrate remaining nutrient solutions to the detriment of growingplants. Conventional hydroponic equipment fails to adequately retard theeffects of evaporation, and consequently, increased maintenance isrequired to successfully cultivate plants.

In addition, conventional hydroponic equipment fails to adequatelyprotect plant roots and nutrient solutions from insects and othercontamination. While this problem is not as severe when equipment isused indoors, it becomes serious when used outdoors. Consequently,constant surveillance and maintenance is required outdoors to guardagainst infestations and contamination.

Furthermore, many conventional hydroponic devices are elaboratestructures which are complicated to build and maintain and are thusundesirably expensive. Accordingly, such equipment is not suitable foroutdoor use in applications where the equipment is replicated numeroustimes for the cultivation of large quantities of plants.

SUMMARY OF THE INVENTION

Accordingly, it is an advantage of the present invention that animproved hydroponic apparatus and plant cultivation technique isprovided.

Another advantage of the present invention is that low maintenancehydroponic equipment is provided. Thus, overall expense of operating thepresent invention is reduced and large numbers of the present inventionmay be attended to with a minimum amount of human intervention.

Yet another advantage is that the present invention retards evaporationof nutrient solutions. Consequently, the present invention is suitablefor use in arid climates without requiring excessive maintenance.

Still another advantage is that the present invention guards againstinsect infestations and contamination of plant roots and of nutrientsolutions. Accordingly, the present invention improves survivability ofcultivated plants and reduces required maintenance.

Another advantage is that the present invention is simple to constructand maintain. Thus, the present invention is inexpensive to acquireinitially and to operate.

The above and other advantages of the present invention are carried outin one form by an apparatus which hydroponically cultivates a plantwhile retarding evaporation and protecting plant roots. The apparatusincludes a container which is configured to retain a nutrient solution.The container has an opening therein. A seal is positioned within theopening. The seal has a hole which is dimensioned to provide physicalcontact between the seal and the plant's stem.

The above and other advantages of the present invention are carried outin another form by a method of efficiently cultivating a planthydroponically. The method positions a seed on a porous support mediumwhich resides within a growing container. The growing container has aseal, and the seal has a hole which is located generally above the seed.The method calls for dispersing a nutrient solution throughout thesupport medium located within the growing container. The methodadditionally guides the growth of the plant through the hole in theseal. The stem of the plant is surroundably contacted by the seal. Thus,this surrounding contact retards evaporation of the nutrient solutionfrom the growing container. The seal expands to accommodate the stem asthe plant grows.

BRIEF DESCRIPTION OF THE DRAWINGS

A more complete understanding of the present invention may be derived byreferring to the detailed description and claims when considered inconnection with the FIGURES, wherein like reference numbers refer tosimilar items throughout the FIGURES, and:

FIG. 1 shows a perspective view of a plant grower constructed inaccording with the present invention;

FIG. 2 shows an exploded perspective view of a preferred seal utilizedin the present invention;

FIG. 3 shows a cross sectional view of the present invention at aplanting stage of growth;

FIG. 4 shows a partial cross sectional view of the present inventionafter an initial growth stage;

FIG. 5 shows a partial cross sectional view of the present invention inconnection with a mature plant;

FIG. 6 shows an exploded perspective view of another embodiment of aseal utilized in the present invention;

FIG. 7 shows a partial cross sectional view of the embodiment of FIG. 6in connection with a mature plant;

FIG. 8 shows a cross sectional view of a further embodiment of a sealembodying the present invention;

FIG. 9 is a cross sectional view of another embodiment of a sealembodying the present invention;

FIG. 10 is a cross sectional view of yet another embodiment of a sealembodying the present invention;

FIG. 11 is a perspective view of the seal of FIG. 10 as it would appearprior to installing on an alternate plant grower;

FIG. 12 is a side view of the seal of FIG. 10 as it would appear priorto installation on containers of differing sizes and shapes;

FIG. 13 is a cross sectional view of yet a further embodiment of a sealembodying the present invention;

FIG. 14 is a perspective view of the seal of the present invention as itwould appear being upstaged through a progression of enlarging medium;

FIG. 15 is a perspective view of an alternate embodiment of upstaging ofplant media;

FIG. 16 is a perspective view of an auxiliary seal as it would appearprior to use;

FIG. 17 is a perspective view of the auxiliary seal of FIG. 16 as itwould appear in sealing engagement with a plant;

FIG. 18 is a partial perspective view illustrating coupling means of theauxiliary seal of FIG. 16;

FIG. 19 is a cross sectional view of another embodiment of a sealembodying the present invention;

FIG. 20 is a cross sectional view of yet another embodiment of a sealembodying the present invention;

FIG. 21 illustrates a method of planting a large area employing afurther embodiment of a plant grower;

FIG. 22 is a cross sectional view of the plant grower of FIG. 21;

FIG. 23 is a cross sectional view of maturing plant within the plantgrower of FIG. 21;

FIG. 24 is a cross sectional view of the plant grower of FIG. 21 inconnection with a mature plant;

FIG. 25 is a perspective view of another plant grower;

FIG. 26 is a partial cross sectional view of the grower of FIG. 25;

FIG. 27 is a perspective view of the grower of FIG. 25 as it wouldappear in a storage configuration;

FIG. 28 is a side view of the grower of FIG. 25 as it would appear priorto injection of a nutrient solution;

FIG. 29 is a perspective view of the grower being injected with anutrient fluid;

FIG. 30 is a perspective view of the grower illustrating matured plants;

FIG. 31 is a partial perspective view of a plant grower utilizing awater collection assembly as it would appear in the stored position;

FIG. 32 is a partial perspective view of a plant grower utilizing awater collection assembly as it would appear in the collection position;

FIG. 33 is a partial perspective view of a plant grower utilizing awater collection assembly as it would appear with plant growth;

FIG. 34 is an exploded perspective view of a plant grower utilizing aspool for inserting and removing growing medium;

FIG. 35 is a perspective view of a plant grower utilizing linear seals;

FIG. 36 is a cross sectional end view of the grower of FIG. 35;

FIG. 37 is an exploded perspective view of yet a further embodiment ofthe present invention; and

FIG. 38 is a cross sectional view taken along line 38--38 of FIG. 37

DETAILED DESCRIPTIONS OF THE PREFERRED EMBODIMENTS

FIG. 1 shows a perspective view of a plant grower 10 constructed inaccordance with the teaching of the present invention. Grower 10includes a growing container 12, which may, but is not required to,reside directly on top of ground 14 in an outdoor environment. Supports16 position a holding container 18 slightly above growing container 12.A manifold arrangement 20 couples holding container 18 to growingcontainer 12.

Growing container 12 is constructed from a cylindrically shaped pipe,preferably formed from polyvinyl chloride (PVC) or another plastic.Container 12 includes end caps 22 to seal opposing ends of the pipewhich forms container 12. An upper region 24 of container 12 includes aplurality of openings 26, which are axially spaced apart from oneanother in a line on container 12. The precise number of openings 26 isnot an important parameter in the present invention. However, openings26 are spaced apart from one another by at least a distance whichcorresponds to the maximum density at which the types of plants to becultivated in grower 10 may be grown. Moreover, the size of openings 26is sufficiently large to accommodate the stem diameters of mature onesof such plants.

In addition, manifold arrangement 20 couples to container 12 in aplurality of locations in upper region 24. Manifold arrangement 20serves to selectively and uniformly supply a nutrient solution 27 fromholding container 18 to growing container 12. Thus, an inlet of a valve28 couples to holding container 18, and an outlet of valve 28 couplesthrough a main distribution conduit 30 to each of a plurality ofsecondary distribution conduits 32. Each of secondary distributionconduits 32 couples to upper region 24 of growing container 12. In thepreferred embodiment, manifold arrangement 20 is made from conventionalPVC components and is hermetically sealed when valve 28 is in a closedstate. When valve 28 is closed, no nutrient solution 27 may pass throughmanifold arrangement 20, but when valve 28 opens nutrient solution 27may drain from holding container 18 through manifold arrangement 20 intogrowing container 12.

Growing container 12 additionally includes an evacuation valve 34, whichFIG. 1 shows externally attached to the upper portion of one of an endcap 22. An evacuation tube 36 couples to the opposing side of valve 34from container 12 and extends away from container 12 for a shortdistance. The external end of tube 36 is hermetically sealed from theinterior of container 12 when valve 34 is shut. However, when valve 34opens air may be pumped out from the interior of container 12 throughvalve 34 and tube 36.

Thus, except for openings 26, when valves 28 and 34 are shut theinterior of growing container 12 is hermetically sealed from the outsideenvironment. And, as discussed in more detail below, seals 38 areinstalled within openings 26 to secure openings 26. Generally speaking,a seal 38 hermetically clamps to the entire region of container 12 whichsurrounds an opening 26. Seal 38 includes a centrally located hole 40through which a plant grows. As the plant grows, seal 38 surrounds andcontacts the plant's stem to reduce evaporation of nutrient solution 27from container 12 and to keep insects and contamination outside ofcontainer 12.

The interior of growing container 12 is substantially filled with aninert support medium 42, which supports seeds and growing plant roots.In the preferred embodiment, support medium 42 is a sponge or likematerial which exhibits substantial wicking ability so that nutrientsolution 27 may be evenly distributed throughout medium 42 in upperregion 24 of container 12 and not allowed to seep exclusively into thelower section of container 12. Preferably, support medium 42 is anatural sponge, but may be substantially any porous material, includingbut not limited to porous rubber, cellulose, or other productconventionally recoginized and used as a sponge

Like growing container 12, holding container 18 is constructed from acylindrically shaped pipe, preferably formed from polyvinyl chloride(PVC) or another plastic. Container 18 includes end caps 44 to sealopposing ends of the pipe which forms container 18. In addition, holdingcontainer 18 includes a filler tube 46 and an air escape tube 48 whichattach to the upper sections of holding container 18. Moreover, thelength and diameter of holding container 18 is selected in relationshipto the size of growing container 12 so that when full, holding container18 holds a predetermined quantity of nutrient solution 27. Thispredetermined quantity provides a single charge of nutrient solution 27for growing container 12. This charge of nutrient solution 27 is themaximum quantity of solution 27 which growing container 12 may holdwithout causing harm to plants growing therein, and is determinedempirically.

The apparatus and method of the present invention do not rely on anyparticular nutrient solution. Thus, any of the nutrient solutions knownto those skilled in the art may suitably operate as nutrient solution27.

In operation, a source 50 distributes nutrient solution 27 to holdingtank 18. A tank carried on a truck or trailer may advantageously serveas source 50. Thus, multiple ones of growers 10 may be attended to bysequentially moving source 50 to the multiple growers 10. Preferably,valve 28 is initially shut. Source 50 may quickly fill holding container18 through a hose 52 because holding container 18 contains no internalstructure through which nutrient solution 27 must travel and holdingcontainer 18 includes air escape tube 48. Nutrient solution 27 may bedriven through hose 52 using either a pump or the force exerted bygravity. In addition, the filling of holding container 18 measures adesired quantity of nutrient solution 27 for application to growingcontainer 12. Simultaneously, a hose 54 is coupled between a pump 55 onsource 50 and evacuation tube 36. When evacuation valve 34 is opened,air may be evacuated from the interior of growing container 12. Asdiscussed below, seals 38 collapse around the stems of plants growing ingrowing container 12 to substantially prevent air leakage into container12.

After holding container 18 has been filled with nutrient solution 27 andair has been sufficiently evacuated from within growing container 12,valve 28 is then opened. Consequently, nutrient solution 27 slowlydrains into growing container 12 through manifold 20. Since manifoldarrangement 20 couples to a plurality of points on growing container 12,nutrient solution 27 is distributed evenly within growing container 12.Moreover, since air has been evacuated from container 12, air pocketswithin container 12 and support medium 42 are minimized. Consequently,support medium 42 evenly absorbs and distributes nutrient solution 27.After the contents of holding container 18 have drained into growingcontainer 12, valve 28 may be closed, then holding container 18 mayoptionally be filled again with nutrient solution 27 for future use.

FIG. 2 shows an exploded perspective view of a preferred seal 38 used inconnection with grower 10. Specifically, seal 38 includes a top section56 which mates with a bottom section 58. Top and bottom sections 56-58include bases 60 and 62, respectively. Bases 60-62 are ring-shaped toconform to the section of growing container 12 which immediatelysurrounds opening 26. The bottom of top base 60 and the top of bottombase 62 support gaskets 64 which help to hermetically attach seal 38 tocontainer 12. In addition, the bottom of top base 60 includesbottom-facing snap fastener socket members 66 while the top of bottombase 62 includes top-facing snap fastener plug members 68. As indicatedin FIG. 2, top base 60 is placed outside of container 12 around opening26 while bottom base 62 is placed inside container 12 around opening 26.Next, bases 60-62 are snapped together by inserting plug members 68through separately bored holes or through opening 26 into socket members66. The snapping together of bases 60-62 causes bases 60-62 to tightlyclamp container 12 between gaskets 64. Consequently, a substantiallyhermetic attachment results between bases 60-62 and container 12.

In the preferred embodiment, each of top and bottom sections 56-58 ofseal 38 includes a membrane 70, which extends from the interior ofring-shaped bases 60-62 radially inward to seal hole 40. Preferably,membrane 70 is formed from an impermeable, weather-resistant, resilientmaterial, such as 27 rubber, but it will be appreciated by one skilledin the art that substantially any material which is resilient, to engagea plant, and generally impervious to liquids and gases may be used.Thus, as a plant 72 matures and its stem 74 expands, hole 40 expands toaccommodate stem 74. Each of top and bottom sections 56-58 includes amembrane 70 to provide double protection against seal failure.

Moreover, in the preferred embodiment, membrane 70 is configured toslope upward toward hole 40 from base 60 or 62 when installed oncontainer 12. In order to achieve this three dimensional shape, excessmaterial from membrane 70 is gathered up in pleats 76, which extend frombase 60 or 62 toward hole 40. As pleats 76 approach hole 40, increasedamounts of membrane 70 material are gathered in pleats 76. Thus, asplant stem 74 expands, hole 40 expands without tightly gripping plantstem 74. The upward slope of membrane 70 guides insects and other debrisaway from plant stem 74. However, when air is evacuated from growingcontainer 12, as discussed above, lowered pressure within container 12urges membrane 70 to tightly grip plant stem 74 temporarily to securethe seal against stem 74.

FIG. 3 shows the operation of the present invention at a planting stagein the life cycle of plant 72. Thus, plant 72 is merely a seed 78. Asdiscussed above, container 12 contains nutrient solution 27, which hasbeen absorbed upward by support medium 42. A hollow tube 80, such as aconventional drinking straw, has been inserted into growing container 12through hole 40 in seal 38. Tube 80 has been inserted until one of itsends contacts support medium 42 within container 12. The other of itsends extends out from seal 38. Preferably, hole 40 is sufficiently smallthat it contacts tube 80. Tube 80 functions to keep seed 78 in placedirectly underneath hole 40 so that it cannot easily be dislodged fromits resting place and so that its future growth will be guided outthrough hole 40. In addition, tube 80 preferably has transparent wallsso that it channels light down to seed 78 to enhance germination of seed78.

FIG. 4 shows the operation of the present invention after an initialgrowth stage in the life cycle of plant 72. Thus, plant seed 78 hassprouted and a small stem 74 has now grown through tube 80. In addition,small roots 82 have formed and are anchoring plant 72 in place onsupport medium 42.

At the stage of development illustrated in FIG. 4, the small diameter oftube 80 does not restrict growth of plant 72. However, as plant 72continues to grow, its stem 74 expands. In the preferred embodiment,tube 80 is constructed from a material, such as paper or a biodegradableplastic, which easily breaks apart. Thus, by the time plant 72 reachesthe growth stage where tube 80 would otherwise impede growth, tube 80naturally breaks apart and such growth is not impeded.

FIG. 5 shows the operation of the present invention as plant 72 reachesa mature stage in its life cycle. As illustrated in FIG. 5, tube 80 hascompletely broken apart and no longer surrounds stem 74. Plant 72 hasgrown so that stem 74 is now much larger than the diameter of tube 80.In addition, as stem 74 has expanded, hole 40 in seal 38 has expanded toaccommodate the growth in plant 72.

FIG. 6 shows an alternate embodiment of a seal generally designated 84which may be used in plant grower 10. Seal 84 includes a top section 86which mates with a bottom section 88. Top and bottom sections 86-88include bases 90 and 92, respectively. Bases 90-92 are ring-shaped toconform to the section of growing container 12 which immediatelysurrounds opening 26. The bottom of top base 90 and the top of bottombase 92 support gaskets 94 which help to hermetically attach seal 84 tocontainer 12. In addition, the bottom of top base 90 includesbottom-facing snap fastener socket members 96 while the top of bottombase 92 includes top-facing snap fastener plug members 98. As indicatedin FIG. 6, top base 90 is placed outside of container 12 around opening26 while bottom base 92 is placed inside container 12 around opening 26.Next, bases 90-92 are snapped together by inserting plug members 98through separately bored holes or through opening 26 into socket members96. The snapping together of bases 90-92 causes bases 90-92 to tightlyclamp container 12 between gaskets 94. Consequently, a substantiallyhermetic attachment results between bases 90-92 and container 12.

Top and bottom sections 86-88 of seal 84 include a membrane 100 and 102respectively, extending from the interior of ring-shaped bases 90-92inward to a seal hole 104. Tube 80 as described previously is showninserted through hole 104. As with membranes 70, membranes 100-102provide double protection against seal failure. However, in thisembodiment while membrane 70 is configured to slope upward toward hole40 from base 62 when installed on container 12, membrane 102 isconfigured to slope downward toward hole 104 from base 92. It will beappreciated by those skilled in the art that upward and downward arerelative terms and are intended to refer to the direction of plantgrowth and root growth respectively. In some instances, such as when anopening is formed in the side of a growing container, the upwarddirection with respect to the seals is intended to be in a directionoutward from the container, and downward is intended to be in adirection inward with respect to the container.

In order to achieve this three dimensional shape, excess material frommembranes 100-102 is gathered up in pleats 106, which extend from base90 and 92 respectively toward hole 104. As pleats 106 approach hole 104,increased amounts of membrane 100-102 material are gathered in pleats106. Thus with reference to FIG. 7, as plant stem 108 expands, hole 104expands without excessively gripping plant stem 108. The upward slope ofmembrane 100 guides insects and other debris away from plant stem 108while the inward or downward slope of membrane 102 guides nutrientsolution contained within container 12 away from hole 104 preventingleakage when inverted as shown in FIG. 7. When air is evacuated fromgrowing container 12, as discussed above, lowered pressure withincontainer 12 urges membrane 100 to tightly grip plant stem 108temporarily securing the seal against stem 108. When the container isinverted, for whatever reason, nutrient solution pushes against membrane102, urging it to tightly grip plant stem 108, temporarily securing theseal against stem 108 and preventing leakage of nutrient solution.

FIG. 8 show another embodiment of a seal generally designated 110. Seal110 is generally identical to seal 84, including a top section 112having a top base 114 and a bottom section 116 having a bottom base 118.However, in this specific embodiment, top base 114 and bottom base 118are formed into an integral member with a groove 120 circumscribing seal110 intermediate base 114 and base 118. Seal 110 is fabricated of aflexible material as described previously, which can be deformed forinsertion of bottom section 116 through opening 26 of container 12. Whenproperly inserted, the section of growing container 12 which immediatelysurrounds opening 26 is received within groove 120. The bottom of topbase 114 and the top of bottom base 118 contact the section of growingcontainer 12 which immediately surrounds opening 26, substantiallyhermetically attaching seal 110 to container 12.

FIG. 9 illustrates another embodiment of a seal generally designated122. Seal 122 is generally identical to seal 110, including a topsection 124 having a top base 126 and a bottom section 128 having abottom base 130. Top base 126 and bottom base 130 are formed into anintegral member with a groove 132 circumscribing seal 122 intermediatebase 126 and base 130. As with seal 110, the section of growingcontainer 12 which immediately surrounds opening 26 is received withingroove 132 of seal 122. Seal 122 differs from seal 110 in that a selfclosing vent 134 is formed in seal 122, extending through top base 126and bottom base 130 adjacent groove 132 and intended to replace orsupplement valves 28 and 34 of plant grower 10. In this manner, a needleadaptor 136, for injecting a nutrient solution or evacuating air isinserted through seal 122, opening 26 and into container 12. A secondvent 138 may also be formed in an identical manner to vent 134, forreceiving a moisture meter 140 therethrough. It will be understood bythose skilled in the art that a single vent may be used to evacuate air,insert a nutrient solution, and receive a moisture meter, or a separatevent may be formed for each.

Due to the nature of the material forming seal 122, preferably rubber, aslit through the material is sufficient to form vent 134, which isnormally closed by the surfaces of the slit pressing against oneanother. Vent 134 may be opened by inserting an instrument therethrough,such as moisture meter 140, forcing the surfaces of vent 134 apart. Thesurfaces of vent 134 close around and seal the inserted instrument.

FIG. 10 illustrates another embodiment of a seal generally designated142. Seal 142 is generally identical to seal 38, including a top section144 having a top base 146, and a membrane 148 extending inward andsloping upward to an opening 150 as described previously in conjunctionwith FIG. 2, and a bottom section 152 having a bottom base 154. Seal 142is also similar to seal 110 in that top base 146 and bottom base 154 areformed into an integral member with a groove 156 circumscribing seal 142intermediate base 146 and base 154. However, bottom section 152 includesa membrane 158 which extends inward and slopes upward, within membrane148, to an opening 160 as opposed to sloping downward.

FIG. 11 illustrates a plant grower generally designated by the referencecharacter 162. Plant grower 162 includes seal 142 described previouslyand a growing container 164. In this embodiment, growing container 164is any common container 166 having a cover 168, such as a tub used tocontain butter, margarine, etc. which may be purchased at substantiallyany grocery store. Cover 168 is generally included when purchasing aproduct, and sealingly engages container 166. Container 166 and cover168 can be easily converted for the intended use by forming an opening170 in cover 168. Bottom section 152 of seal 142 is inserted throughopening 170 of growing container 164. When properly inserted, theportion of cover 168 which immediately surrounds opening 170 is receivedwithin groove 157. The bottom of top base 146 and the top of bottom base154 contact the section of cover 168 which immediately surrounds opening170, substantially hermetically attaching seal 142 to growing container164.

Recycling commonly used container 166 in this manner provides a smallinexpensive lightweight plant grower. While not specifically shown,growing container 164 may include a support media as previouslydescribed, for supporting roots and containing nutrient solution. Thoseskilled in the art will also appreciate that while growing container 164as shown would require removal of cover 168 for insertion of nutrientsolution, vent 134 as described in FIG. 9 may be formed in seal 142.This would allow evacuation of air from within container 164, andinjection of a nutrient solution in a manner similar to that describedpreviously.

FIG. 12 is intended to illustrate that containers 172 of many differentsizes and shapes may be converted to plant growers by forming openingsin their respective covers 174 and inserting a seal 142.

FIG. 13 illustrates another embodiment of a seal generally designated178 which may replace seals in plant grower 10. Seal 178 is generallyidentical to seal 110, including a top section 180 having a top base182, and a membrane 184 extending inward and sloping upward to anopening 186, and a bottom section 188 having a bottom base 190. Seal 178is also similar to seal 110 in that top base 182 and bottom base 190 areformed into an integral member with a groove 192 circumscribing seal 178intermediate base 182 and base 190. However, bottom section 188 includesa membrane 194 which extends inward and slopes upward, substantiallyparallel to membrane 184 before flaring downward to an opening 196. Theupward slope of membrane 194 raises opening 196 to a level generallyeven with bottom base 190. In this configuration, bottom section 188 ofseal 178 is flush with support medium 42. While the downward flaring ofmembrane 194 is sufficient so that when the container is inverted ortilted, nutrient solution pushes against membrane 194, urging it totightly grip the plant stem, temporarily securing the seal against thestem and preventing leakage of nutrient solution, membrane 194 does notextend into container 12 far enough to hinder removal of support medium42 from container 12. Since bottom section 188 of seal 178 issubstantially flush with support medium 42, support medium 42 may beremoved without damage and without requiring the prior removal of seal178.

FIG. 14 illustrates an upgrade system for increasing the size of thesupport medium as a plant grows. In this manner, a plant 198 in a smallplant grower 200 can be transplanted. Plant grower 200 initiallyincludes a seal which may be seal 142 or seal 178, but for purposes ofbrevity will be referred to as seal 178 in this embodiment, a growingcontainer 202, and a support medium 204 carried by growing container202. As plant 198 increases in size and its root system expands to thelimits of growing container 202, plant 198 with seal 178 is removed fromcontainer 202, and inserted into an expander 206. Expander 206 is acylindrical section constructed of material substantially identical tosupport medium 204, having a cavity 208 formed therein for receivingsupport medium 204. The consequence is to effectively increase the sizeof the support medium without disturbing the root system of the plant.Expander 206 may, in turn, be inserted into a larger expander 210 havinga cavity 212. Upgrading the size of the support medium may also requirea larger growing container.

FIG. 15 shows an upgrade system substantially identical to thatillustrated in FIG. 14, with the difference being that a plurality ofplants 214 are grown in a plurality of generally cuboidal support media216, serially attached. As the root system of each plant 214 reaches thelimit of its respective support medium 216, support medium 216 areseparated and each inserted into one of a plurality of generallycuboidal expanders 218. Expanders 218 each have a cavity 220 forreceiving support media 216, and, in this embodiment, are seriallyattached as were support media 216. Expanders 218 may be separated asthe root system of each plant 214 reaches the new limit, and eachexpander 218 inserted into a cavity 222 a larger expander 224.

FIGS. 16 and 17 show an auxiliary seal 226 to be used in combinationwith seal 38, and seal 142 or any subsequent seals having a bottomsection with an upward sloping membrane. Auxiliary seal 226 is a roundgenerally planar member, having an edge 228 and a centrally locatedopening 230. Auxiliary seal 226 has a plurality of striations 232extending from edge 228 to opening 230, dividing it into pie shapedwedges 234. Auxiliary seal 226 is attached to the underside of thebottom section of the seal, within the container. As a plant 236 grows,illustrated by broken lines, its stem 238 forces wedges 234 to separatealong striations 232 beginning adjacent opening 230 and graduallyexpanding as stem 238 thickens. As wedges 234 separate, each wedge 234is compressed by stem 238, enlarging opening 230. Preferably, wedges 324are compressed radially outward, however, as shown in FIG. 17 a slightupward slope towards opening 230 may occur. The gradual separation ofwedges 234 insures a snug fit between auxiliary seal 226 and stem 238,preventing leakage of nutrient solution.

FIG. 18 shows attachment means for attaching auxiliary seal 226 to thebottom section of the seal. Attachment means preferably consists of anadhesive 240 applied to the periphery of a top surface 242 of auxiliaryseal 226, protected by a peel strip 244. When attachment of auxiliaryseal 226 is desired, peel strip 244 is removed and auxiliary seal 226 ispressed into place.

FIG. 19 illustrates another embodiment of a seal generally designated246. Seal 246 is configured to engage and close a container 248 having arim 250. Seal 246 includes a cylindrical collar 252 having an upper edge254 and a lower edge 256 and a membrane 258 extending radially inward toa seal hole 260. Membrane 258 slopes upward toward hole 260 from collar252 when installed on container 248. As with previously describedmembranes, in order to achieve this three dimensional shape, excessmaterial from membrane 258 is gathered up in pleats (not visible)extending from collar 252 toward hole 260. As the pleats approach hole260, increased amounts of membrane 252 material are gathered in thepleats. Thus, as a plant stem expands, hole 260 expands without tightlygripping the plant stem and causing damage or hindering growth. Theupward slope of membrane 258 guides insects and other debris away fromthe plant stem. Collar 252 is formed from an impermeable,weather-resistant, elastic material, such as rubber, and is expandableto encompass and constrictively engage rim 250 of container 248. Theelastic nature of collar 252 allows it to expand and engage a range ofcontainer sizes as well as to effectively seal container 248.

FIG. 20 is yet a further embodiment of a seal generally designated 262.Seal 262 is generally identical to seal 142, including a top section 264having a top base 266, and a membrane 268 extending inward and slopingupward to an opening 270, and a bottom section 272 having a bottom base274 and a membrane 276 extending inward and sloping upward to an opening278. Top base 266 and bottom base 274 are formed into an integral memberwith a groove 280 circumscribing seal 262 intermediate base 266 and base274. However, in this specific embodiment, membranes 268 and 276 areeach separated into a plurality wafer like layers 282, separated atopening 278, establishing a greater sealing potential about a plant stemsince wafers layers 282 effectively form multiple seals.

FIGS. 21-24 show a method of planting a large area using a furtherembodiment of a plant grower generally designated 284. Referringspecifically to FIG. 21, plant grower 284 is ejected from a transportapparatus such as an airplane 286. Plant grower 284 comes to rest upon asurface 288 upon which plant growth is desired. Plant grower 284 willprotect roots 290 of plant 292 from the environment while immature,providing nutrient solution and support for its stem 294 untilsufficiently grown to survive on its own, or until extra support can beimplemented.

It can be seen with reference to FIG. 22, that plant grower 284 includesa substantially spherical container 296 carrying a support medium 298and a nutrient solution 300. Container 196 has a contact portion 302designed to rest upon surface 288, side portion 304 and a seal 306generally opposing contact portion 302. Side portion 304 and seal 306are preferably formed from identical material which is elastic andsemipermeable, having osmotic properties. In other words, water fromoutside may enter container 296 through side portion 304 and seal 306,but moisture will not move outward from container 296. It will beunderstood that side portion 304 may be fabricated of osmotic materialwhile seal 306 is formed from material identical to previously describedseals, with seal 306 bonded to side portion 304. Contact portion 302 isrequired to be formed from a degradable material for purposes which willbe described subsequently. Seal 306 may be substantially identical toany of the preceding embodiments, but is preferably similar to seal 246without collar 252. Seal 306 includes a membrane 308 integral with sideportion 304 and sloping upward to a central opening 310. Seal 306 willprevent loss of nutrient solution 300 and will support and protectimmature plant 292. As plant 292 matures opening 310 expands with theexpansion of the maturing stem 294 as described in previous embodimentsand shown in FIG. 23. As time passes and roots 290 continue to fillcontainer 296, contact portion 302 degrades and is broken apart by roots290. At this point plant 292 begins to take root in surface 288 as shownin FIG. 24.

FIG. 25 shows yet a further embodiment of a plant grower generallydesignated 312, to be used to grow food plants for grazing animals orground cover such as grass for a lawn. Plant grower 312 includes aflexible container 314 preferably being an elongated rectangular boxhaving a seal layer 316 through which a closable valve 318 extends.Container 314 is preferably fabricated from nontoxic degradablematerial. With additional reference to FIG. 26, container 314 includes abase 320 with sidewalls 322 containing a support medium 324 preferable aporous material having wicking properties. Seal layer 316 is coupled tosidewalls 322 enclosing support medium 324. Parallel layers 326 of apenetrable material such as cheese cloth or perforated paper overliesupport medium 324 beneath seal layer 316 for supporting seeds 328therebetween. Seal layer 316 in this embodiment is fabricated of adegradable material which may also be consumed by grazing animals. Apreferred material for seal layer 316 is gelatin which may be harden bypolishing with vegetable oil or carnuba wax. The point being, that whenplant grower 312 is used to grow pasturage for grazing animals, it wouldcontain nothing harmful to those animals. When used to grow sod or otherground cover, plant grower 312 would be biodegradable, allowing theplants to take root in the undersurface. The use of plant grower 312 forgrowing sod would reduce the amount a water needed, and protect seeds328 from seed eating animals such as birds and insects.

With reference to FIGS. 27 and 28, plant grower 312 would be evacuated,to reduce air within container 314 and support medium 324. With reducedinterior air pressure, sidewalls 322 of container 314 would collapse inan accordion fashion illustrated in FIG. 28. Plant grower 312 may thenbe rolled into a compact bundle 330 easily transportable.

Referring now to FIGS. 29 and 30, when a surface 332 to be planted islocated or pasturage is required, bundle 330 is unrolled and a hose 334for providing a nutrient solution is coupled to valve 318. Nutrientsolution is distributed equally throughout support medium 324 due to itswicking characteristics, reinflating container 314. At this time seeds328 will begin to germinate, producing immature plants 336 which forcetheir way through seal layer 316. When the plants mature, grazinganimals can be given access, or eventually container 314 will degradeallowing the plants to root in surface 332.

FIGS. 31 and 32 show a water collection system for use with a pluralityof parallel plant growers 340 substantially similar to plant grower 10.Each of plant growers 340 are suspended with an end 342 positioned overa collection reservoir 344. A curtain 346 of water proof material issuspended between plant growers 340 and slidably extendable along tracks348 attached to the outer surface of plant growers 340. FIG. 31illustrates curtains 346 when bunched near end 342. This permits tendersto walk between plant growers 340 and tend to the plants. FIG. 32illustrates curtains 346 when extended along tracks 348 between plantgrowers 340. In this position precipitation can be collected andchanneled to reservoir 344 for future use.

FIG. 33 illustrates the plurality of plant growers 340 with plantsgrowing therefrom.

FIG. 34 shows a spindle 350 for removing and inserting support medium352 within a plant grower. Growing container 12 of plant grower 10 isillustrated, with seals 38 removed from openings 26 and end cap 22removed. Spindle 350 includes an axially extending rod 354 carryingspaced apart laths 356 constructed of water permeable material such aswire mesh. Laths 356 are preferably round to slide easily within growingcontainer 12 and spaced to form a separation between each opening 26. acylindrical section 358 of support medium 352 is positioned on rod 354between each of laths 356 to provide support for plants and containnutrient solution. After the plants have been harvested, support medium352 must be removed and new or cleaned support medium inserted. This iseasily accomplished by removing spindle 350 and replacing sections 358.By using spindle 350, compression and unequal distribution of supportmedium 352 is avoided. Furthermore, seeds 360 may be placed upon eachsection 358 prior to inserting new support medium in preparation forgrowing a new crop.

FIGS. 35-36 show an alternate embodiment of a plant grower generallydesignated 362. Plant grower 362 includes a cylindrical container 364,preferably of the corrugated metal piping commonly used as culverts. Adivider 366 is positioned within container 364, separating it into a topportion 368 and a bottom portion 370. A support medium 372 is carriedwithin top portion 368 to support and supply nutrient solution 374 orwater to plants 376. Bottom portion 370 is used as a reservoir forstoring nutrient solution 374 to be used in top portion 368. A pluralityof openings 378 are formed in top portion 368 of container 364preferably between corrugations, but it will be understood that they maybe alternatively formed on each corrugation. When plants 376 needadditional nutrient solution 374, a tender will use a conventional fluidtransfer device for transferring nutrient solution from bottom portion370 to top portion 358.

Plant grower 362 also includes linear seals 380 having a generallyrectangular base 382 from which a membrane 384 extends inwardly to aslot 386. Base 382 is coupled to the portion of container 364surrounding openings 378. Preferably, membrane 384 is formed from animpermeable, weather-resistant, resilient material, such as rubber.Thus, as a plant 376 matures and expands, slot 386 expands toaccommodate it.

FIGS. 37-38 show another embodiment of a plant grower generallydesignated 390, functioning mainly as an educational tool, allowing thegrowth of a plant to be viewed. Plant grower 390 includes an elasticframe 392 having a front edge 394 and a back edge 396, a fronttransparent panel 398 carried by frame 392 proximate front edge 394, anda back transparent panel 400 carried by frame 392 opposite front panel398 proximate back edge 396. Frame 392 includes a pair of opposing sides402, coupled by a top 404 and a substantially parallel bottom 406.Preferably, frame 392 is formed from rubber, and fabricated in a singleintegral piece. A pair of channels 408 and 410 are formed around theperiphery of the inner surface of frame 392, proximate front edge 394and back edge 396 respectively. Channels 408-410 receive panels 398 and400 respectively forming a fluid tight seal therewith. Insertion andremoval of panels 398 and 400 is possible due to the elastic property offrame 392 which can be expanded away from panels 398 and 400 for removaland insertion, and which will compressively engage panels 398 and 400forming a fluid tight seal. 412 each include a membrane 414 extendingradially inward to an opening 416. Preferably, membrane 414 is formedfrom and integral with the elastic material of frame 392. Thus, as aplant matures and its stem expands, opening 416 expands to accommodatethe stem. Moreover, in the preferred embodiment, membrane 414 isconfigured to slope upward toward opening 416 from frame 392. In orderto achieve this three dimensional shape, excess material from membrane414 is gathered up in pleats 418, which extend from frame 392 towardopening 416. As pleats 418 approach opening 416, increased amounts ofmembrane 414 material are gathered in pleats 418. Thus, as the plantstem expands, opening 416 expands without tightly gripping the plantstem and hindering growth. While three seals 412 are illustrated, itwill be understood that the number of seals 412 is not important to theinvention, and substantially any number of seals 412 from one or moremay be used. Furthermore, it will be understood that seals 412 may beseparate from frame 392 and attached and removed at will.

In summary, the present invention provides an improved hydroponicapparatus and plant growing technique. The apparatus of the presentinvention is constructed from inexpensive components. Moreover, plantsgrowing outdoors within the apparatus of the present invention need lessmaintenance because seals are provided to reduce evaporation, insectinfestation, and other contamination. In addition, a structure isprovided so that nutrient solution may be delivered quickly. As aresult, a large number of plants may be attended to in a short period oftime and at low cost.

The present invention has been described above with reference to anumber of embodiments. However, those skilled in the art will recognizethat changes and modifications may be made in these embodiments withoutdeparting from the scope of the present invention. For example, thepresent invention may be buried underground for aesthetic or otherreasons. Various embodiments of the seals may also be interchanged withthe different embodiments of plant growers. It will also be appreciatedby one skilled in the art that the various described auxiliary devices,such as vents of FIG. 9, used to evacuate air and insert nutrientsolution may be used with any of the plant growers and seals. Inaddition, additional provisions may be provided for draining nutrientsolutions from the containers of the present invention. These and otherchanges and modifications which are obvious to those skilled in the artare intended to be included within the scope of the present invention.

What is claimed is:
 1. An apparatus for hydroponically cultivating aplant having roots and a stem and for retarding evaporation whileprotecting said plant roots, said apparatus comprising:a containeradapted to retain a nutrient solution, said container having an openingtherein; a seal coupled to a section of said container which immediatelysurrounds said opening, said seal having a hole therein, said hole beingdimensioned for physical contact between said seal and said plant stem;a porous support medium into which said plant roots grow, located withinsaid container proximate said opening; and a hollow tube beingsufficiently long to contact said support medium while projectingoutward from said container through said seal hole, said hollow tubebeing for retaining a plant seed in position relative to said seal holeand for guiding growth of said plant through said seal hole.
 2. Anapparatus as claimed in claim 1 wherein said hollow tube is constructedfrom a material which breaks apart as said plant grows.
 3. An apparatusas claimed in claim 2 wherein said hollow tube transmits light toenhance germination of said seed.
 4. An apparatus as claimed in claim 1wherein said seal comprises a resilient material configured so that saidseal hole expands to accommodate growth of said plant.
 5. An apparatusas claimed in claim 4 wherein said seal achieves a substantiallyhermetic attachment to said container.
 6. An apparatus as claimed inclaim 5 wherein said seal hole is centrally located in said seal, andsaid seal is formed from a membrane having expandable pleats extendingoutward from said seal hole, said pleats being expandable to permit saidseal hole to expand without tightly gripping said plant stem.
 7. Anapparatus as claimed in claim 5 wherein said seal further includes:a topsection having a top base, positioned outside of said container andconforming to said section of said growing container immediatelysurrounding said opening, and a top membrane extending from said topbase inwardly to said seal hole; and a bottom section having a bottombase underlying said top base, positioned within said container andconforming to said section of said growing container immediatelysurrounding said opening, and a bottom membrane extending from saidbottom base inwardly to said seal hole.
 8. An apparatus as claimed inclaim 7 wherein said seal hole is centrally located in said top andbottom membranes, said top and bottom membranes each having expandablepleats extending inward from said respective base to said seal hole,said pleats being expandable to permit said seal hole to expand withouttightly gripping said plant stem.
 9. An apparatus as claimed in claim 7wherein said top membrane is configured to slope from said top base tosaid seal hole in a direction outward from said container.
 10. Anapparatus as claimed in claim 9 wherein said bottom membrane isconfigured to slope from said bottom base to said seal hole in adirection outward, toward said top membrane.
 11. An apparatus as claimedin claim 9 wherein said bottom membrane is configured to slope from saidbottom base to said seal hole in a direction inward, away from said topmembrane.
 12. An apparatus as claimed in claim 9 wherein said sealfurther includes fastening means for fastening said bottom base to saidtop base.
 13. An apparatus as claimed in claim 12 wherein said fasteningmeans includes an element of an engagement pair extending from a bottomof said top base, and a complemental element of said engagement pairextending from a top of said bottom base.
 14. An apparatus as claimed inclaim 5 wherein said seal includes a sealable vent extendingtherethrough for selective transmission of said nutrient solution intosaid container, and for selective evacuation of air from said containerto enhance distribution of said nutrient solution within said container.15. An apparatus as claimed in claim 5 wherein said containercomprises:a first valve adapted for selective transmission of saidnutrient solution into said container; and a second valve adapted forselective evacuation of air from said container to enhance distributionof said nutrient solution within said container.
 16. An apparatus asclaimed in claim 1 further including a spindle for removably insertingsaid support medium into said container, wherein said container includesa generally cylindrical pipe having a first end and a second end, eachclosed by an end cap.
 17. An apparatus as claimed in claim 16 whereinsaid spindle includes an axially extending member carrying spaced apartlaths between which said support medium is carried.
 18. An apparatus asclaimed in claim 5 further comprising an auxiliary seal coupled withinsaid container, underlying said seal.
 19. An apparatus as claimed inclaim 18 wherein said auxiliary seal includes a planar member fabricatedof an elastic material, a centrally positioned opening formed in saidplanar member, and striations formed in said planar member, radiatingoutward from said opening, dividing said planar member into section,individually compressible by said stem.
 20. An apparatus as claimed inclaim 4 wherein said container further includes:a contact portionconfigured to engage a surface, said contact portion constructed of amaterial which breaks apart as said plant grows; and a side portionextending from said contact portion and defining said opening, said sideportion constructed of a semipermeable material having an osmoticcharacteristic allowing one way passage of water into said container.21. An apparatus for hydroponically nurturing a seed into a plant havingroots and for protecting said seed and retarding evaporation, saidapparatus comprising:a container adapted to retain a nutrient solution,said container having an opening therein, said container beingconstructed of a material which will break apart as said plant growsallowing said roots to extend through said container; a seal layerfabricated of stiffened gelatin extending across said opening, sealingsaid container, said seal layer pierceable by said growing plant; aporous support medium into which said plant roots grow, located withinsaid container; positioning means captured between said seal layer andsaid support medium for positioning said seed, wherein said positioningmeans is a pair of substantially parallel penetrable layers capturingsaid seed therebetween; and a valve coupled to said seal layer forevacuating air within said container, and injecting said nutrient fluid.